Abstract
The rising scarcity of potable water, coupled with environmental concerns over conventional purification methods, has accelerated the global shift toward renewable energy-based clean water solutions. Solar stills, with their simplicity, sustainability, and low operating costs, present a promising option for decentralized water purification. This study examines three solar still designs-rectangular, conical, and hemispherical-under identical conditions to identify the most efficient configuration based on key performance outcomes. However, the intricate nonlinear relationships among the output parameters and the geometric complexities of the stills pose significant challenges to conventional optimization techniques. To overcome these limitations, a hybrid methodology is employed, incorporating a priority-based clustering model to systematically optimize and identify the ideal solar still design. The integrated analysis reveals strong thermal-performance relationships, with heat transfer coefficient (h) showing high correlations with Tw, Tg, and Ta (r > 0.77, Adj R(2) ≈ 0.89), while Qew is strongly linked to Tg (r = 0.9284), Tw (r = 0.8941), and h (r = 0.9221); Mew exhibits an almost perfect correlation with Qew (r = 0.9998, Adj R(2) ≈ 0.9971). The ANN model using the Gaussian membership function demonstrated the highest prediction accuracy with R(2) = 0.997, RMSE ≈ 0.14%, and MSE ≈ 0.01%. Priority weighting favoured Mew at 39%, followed by η (28%), Qew (19%), and h (14%), improving clustering accuracy. K-means clustering pinpointed Trial 27 as optimal, with I(t) = 820 W/m(2), Ta = 37 °C, Tw = 59 °C, and Tg = 53 °C, yielding the best thermal synergy for maximum solar still performance.